DE102017003473A1 - Single-laminating machine - Google Patents

Abstract

The invention relates to a Einschneckenplastifiziermaschine for processing a starting material, preferably for processing thermoplastic polymers or fusible foods. In this case, the screw of the single-screw plasticizing machine has at least one barrier zone. The pitch of the main and / or the pitch of the barrier web is to be changed several stages in the range of 5% of the axial length of the barrier zone to 50% of the axial length of the barrier zone.

Description

The invention relates to a single-screw plasticizing machine and, in particular, to the configuration of the screw of a single-screw plasticizing machine. In the single-screw plasticizing machine, any starting material should be able to be processed. Preferably, the starting material should be at least partially meltable. In addition to the fusible portion, non-fusible components, e.g. Wood, calcium carbonate, sand, glass fibers, carbon black, mineral substances or the like may be included. It is preferred to process thermoplastic polymers and additives or fillers needed for processing on the single-screw plasticizing machine. In addition, fusible foods can be processed on the single-screw plasticizer.

In addition to the starting material, referred to hereinafter as solids, the single-screw plasticizing machine can also be supplied with other materials in the liquid or gaseous state, which can also be present at least partially in the melt to be produced.

Single-screw plasticizing machines are known and proven in various embodiments. They are used, for example, in the plastic processing of the plastification of a first mostly granular or powdered solid, mostly plastic raw material, the promotion of the melt produced and the pressure build-up for a subsequent tool, for example an injection mold or an extrusion tool. A similar structure can be found in the processing of fusible foods.

Single-screw plasticizing machines are becoming increasingly common in a so-called barrier zone in which both solid and melt are present. The barrier zone is characterized in that the flight path formed by a main web is an additional screw flight, the so-called barrier web, which divides the flight into two sections, the solid channel and the melt channel. While in the melt channel is generally almost exclusively melt, in the solid channel already present in addition to the solid and a not insignificant amount of melt.

The requirements for a single-screw plasticizing machine are very numerous. Thus, after leaving the single-screw plasticizing machine, the solid should be present as a melt which is as homogeneous as possible both mechanically and thermally. Furthermore, the melt should usually have the lowest possible temperature. These properties should be achieved over the widest possible range of materials.

A variety of differently designed single-screw barrier-type plasticizers are known in the art.

The US 3358327 describes a barrier-zone single-screw plasticizer, the barrier bar having a diagonal course from the active to the passive edge of the main bar. As a result, the width of the solids channel decreases continuously, while the width of the melt channel increases continuously. In the middle of the barrier zone, the solid channel has approximately only half the width in comparison to the beginning of the barrier zone. By the continuous reduction of the width of the solids channel along the barrier zone, on the one hand, the possible introduction of energy into the solid is reduced and, on the other hand, the risk of blockage of the solid bed in the solids channel is unnecessarily increased. At the same time along the barrier zone, the width of the melt channel and thus the energy input into the melt increases. This unnecessary energy input can lead to an increase in the melt temperature.

The US 3698541 describes a barrier-zone single-screw plasticizer with the barrier bar having the same pitch as the major bar over a long range. In this variant of the barrier zone, the width of the solids channel decreases significantly at the beginning of the barrier zone. On the one hand, this reduces the possible introduction of energy into the solid and, on the other hand, unnecessarily increases the risk of blockage of the solid bed in the solids channel at the beginning of the barrier zone. At the same time, the melt channel with a relatively large width is already present shortly after the beginning of the barrier zone, which leads to a higher energy input into the melt. This unnecessary energy input can lead to an increase in the melt temperature.

The DE 2121914 A1 describes a barrier-zone single-screw plasticizing machine with the main web having a greater pitch at the beginning of the barrier than in the feed zone. In this variant of the barrier zone, the width of the solid channel at the beginning of the barrier zone is minimized, if at all, only insignificantly and remains almost constant during a majority of the barrier zone. As a result, on the one hand the possible energy input into the solid is kept at a high level and, on the other hand, the risk of blocking of the solid bed in the solids channel at the beginning of the barrier zone is reduced. Due to the almost constant course of the width of the solid channel, however, no discontinuous rearrangement processes take place in the solid bed, whereby the Degree of performance of the melting of the solid is limited.

At the same time, the melt channel with a relatively large width is already present shortly after the beginning of the barrier zone, which leads to a higher energy input into the melt. This unnecessary energy input can lead to an increase in the melt temperature.

The US 2011217406 A1 also describes a barrier-zone single screw plastifying machine in which the main web has a greater pitch at the beginning of the barrier than in the feed zone. At the same time the pitch of the barrier bar is changed. This is intended to maintain the width of the solids region in the barrier zone at a similar level as present in the feed zone. Again, the width of the melt channel over a large part of the length of the barrier zone to be kept constant and quickly reach this width. There are therefore the same disadvantages or limitations as in the DE 2121914 A1 namely, a low degree of melting in the solids channel and a possible increase in the melt temperature.

Hereinafter, reference is often made to an axial direction or an axial length. By an axial direction is meant the direction along the screw axis. This direction is in 1 marked with the arrow 10. The axial length of, for example, the barrier zone is the length of the barrier zone along the screw axis. The length of the barrier zone along the screw axis is referred to below as the barrier zone length. In the following, the step area is the area which begins at 5% of the barrier zone length and ends at 50% of the barrier zone length, ie along the screw axis, exactly in the middle of the barrier zone.

The invention has for its object to provide the prior art an improvement or an alternative.

According to a first aspect of the invention, this object is achieved by a single-screw plasticizing machine having a barrier zone in which at least the pitch of one of the two webs present in the barrier zone, ie the main web and / or the barrier web, is changed several times in the step area. In this case, the pitch of the respective web is to be changed gradually 3 to 1000 times, preferably 5 to 500 times, 5 to 300 times, 8 to 300 times, 8 to 100 times, particularly preferably 10 to 80 times. There can be any distribution of incremental changes in the step area. Due to the gradual changes in the pitch in the step area, discontinuous rearrangement processes take place in the solid bed, which leads to an improved melting of the starting material. The size of the changes should be chosen so that discontinuous rearrangements of the solid bed are possible, but the risk of blocking the solid bed is low. Depending on the type of starting material used or the form of the starting material, a small number of rather larger incremental changes may make sense, or a greater number of rather small incremental changes, or a mixture of both.

Also, in front of or behind the step area, there may be changes in pitch, including stepwise changes, in the barrier zone or outside the barrier zone, e.g. affect the width ratio of solids channel and melt channel, affect the width of the screw channel or set the inlet and outlet of the barrier bar.

Already the gradual changes of one of the two webs in the step area should be sufficient to ensure multiple discontinuous rearrangements of the solid bed. The stepwise changes of the two webs within the step range, however, makes it possible in a simple manner to increase the number of discontinuous rearrangements while keeping the width of the solids channel as large as possible or nearly constant up to the steps and thus to allow the solid channel a large projection surface to the cylinder. whereby the energy input in the solid remains as large as possible. At the same time, the width of the melt channel can be kept as low as possible, so that the melt channel has a small projection area to the cylinder and thus the energy input into the melt remains as small as possible.

Therefore, preferably the pitches of both webs, so both the main web, as well as the barrier web, are repeatedly changed stepwise in the step area. The quotient from the projection surface of the melt channel to the cylinder (numerator) and the projection surface of the solid channel to the cylinder (denominator) should be as small as 0.35, preferably less than 0.25, to the first 50% of the axial length of the barrier zone. more preferably less than 0.2.

For an efficient and more economical production of the screw, at least a portion of the stepwise changes of the pitch in the step area of the respective web in the axial direction of the barrier zone can be arranged equidistantly, if possible at least 50%, preferably at least 90%, more preferably at least 95% equidistant.

If the stepwise changes in the step area are present on both webs, they may be present at least partially for both webs at the same axial positions of the barrier zone, if possible in at least 50% of the cases, preferably in at least 90% of the cases particularly preferably in at least 95% of the cases.

For more economical production, the incremental changes in the pitch of a land present in the land area may have the same amount of change in pitch. The amount of change should then be equal to at least 30% of the pitch changes of a web in the step area, preferably at least 90%, particularly preferably at least 95%. This type of embodiment can also be applied to both webs, wherein the amount of change of the pitch changes of the barrier web may differ from the amount of change of the pitch changes of the main web, but need not.

For another embodiment for a more economical production, the present stepwise changes in the pitch can be grouped in the step area in such a way that in each case the pitch changes are present in a group having the same amount of change. At least one group must have at least three pitch changes. Preferably, the pitch changes grouped together are at least mostly juxtaposed. This type of embodiment can also be applied to both webs, wherein the respective groups relate to a web.

Insofar as the main web or the barrier web is interrupted at least once due to the present design, in the context of the present specification the parts of the respective web that are present are considered together as "a web". Thus, regardless of interruptions in the barrier web or main web, a barrier web and a main web are present in a single-flight screw.

The invention can be used both with screws, which are catchy at least in the barrier zone of the screw, ie have only a solid channel and a melt channel, as well as with screws that are more in at least in the barrier zone of the screw, so at least two solid channels and two melt channels exhibit.

• 1 zeigt schematisch und nicht maßstäblich eine Einschnecken-Plastifiziermaschine mit einer Schnecke mit Barrierezone.
• 2 zeigt eine schematische, nicht maßstäbliche Abwicklung des Schneckenkanals im Bereich der Barrierezone mit einem diagonalen Barrieresteg.
• 3 zeigt eine schematische, nicht maßstäbliche Abwicklung des Schneckenkanals im Bereich der Barrierezone mit einem Barrieresteg, der über einen Großteil der Länge der Barrierezone parallel zum Hauptsteg verläuft.
• 4 zeigt eine schematische, nicht maßstäbliche Abwicklung des Schneckenkanals im Bereich der Barrierezone mit einem Barrieresteg. Hierbei wird die Gangsteigung sowohl vom Haupt- als auch vom Barrieresteg geändert, wobei dies nicht über mehrere stufenweisen Änderungen erfolgt.
• 5 zeigt eine schematische, nicht maßstäbliche Abwicklung des Schneckenkanals im Bereich der Barrierezone mit Haupt- und Barrieresteg, wobei in diesem Fall nach einer erfindungsgemäßen Ausprägung die Gangsteigungen beider Stege innerhalb des Stufenbereiches der Barrierezone stufenweise mehrfach erhöht werden.
• 6 zeigt schematisch und nicht maßstäblich den Verlauf der Gangsteigung im Stufenbereich der Barrierezone entlang der Schneckenachse nach einer erfindungsgemäßen Ausprägung.

The invention will be explained below with reference to various figures.

• 1 shows schematically and not to scale a Einschnecken plasticizing machine with a screw with barrier zone.
• 2 shows a schematic, not to scale development of the screw channel in the area of the barrier zone with a diagonal barrier web.
• 3 shows a schematic, not to scale development of the screw channel in the area of the barrier zone with a barrier web, which runs over a large part of the length of the barrier zone parallel to the main web.
• 4 shows a schematic, not to scale development of the screw channel in the region of the barrier zone with a barrier web. Here, the pitch is changed from both the main and the barrier bar, this is not done over several gradual changes.
• 5 shows a schematic, not to scale development of the screw channel in the area of the barrier zone with main and barrier web, in which case the pitches of both webs within the step area of the barrier zone are increased stepwise several times in accordance with an inventive feature.
• 6 shows schematically and not to scale the course of the pitch in the step area of the barrier zone along the screw axis according to an embodiment of the invention.

1 shows schematically and not to scale a Einschnecken plasticizing machine with a screw with barrier zone. The dashed line 4 separates the feeder zone as an example 1 from the barrier zone 2 and thus marks the beginning of the barrier zone. The dashed line 5 separates the barrier zone as an example 2 from the metering zone 3 and marks the end of the barrier zone. The barrier jetty 6 separates the snail channel, which passes through the main bridge 9 is generated in a solid channel 8th and the melt channel 7 , The orientation of the screw axis is indicated by the arrow 10 characterized.

2 shows a schematic, not to scale development of the screw channel in the area of the barrier zone with a diagonal barrier bar, similar to that in the US 3358327 described. The dashed line 104 separates the feeder zone as an example 101 from the barrier zone 102 and thus marks the beginning of the barrier zone. The dashed line 105 separates the barrier zone as an example 102 from the metering zone 103 and marks the end of the barrier zone. The barrier jetty 106 starts at the beginning of the barrier zone 102 from the active flank of the main bridge 109 and runs diagonally through the channel to the passive edge of the main bridge 109 , In this case, the channel of solids in the channel 108 and the melt channel 107 generated. Both the pitch of the main bridge 109 , as well as the gangway of the barrier barge 106 are constant, with the barrier bar 106 a higher pitch than the main bridge 109 having. The orientation of the screw axis is indicated by the arrow 110 characterized.

In this variant of the barrier zone, the width of the solids channel decreases continuously along the barrier zone. As a result, on the one hand, the possible energy input into the solid is reduced and, on the other hand, the risk of blockage of the solid bed in the solids channel is unnecessarily increased. At the same time along the barrier zone, the width of the melt channel and thus the energy input into the melt increases. This unnecessary energy input can lead to an increase in the melt temperature.

3 shows a schematic, not to scale development of the screw channel in the area of the barrier zone with a barrier web, which runs over a large part of the length of the barrier zone parallel to the main web, similar as in US 3698541 described. The dashed line 204 separates the feeder zone as an example 201 from the barrier zone 202 and thus marks the beginning of the barrier zone. The dashed line 205 separates the barrier zone as an example 202 from the metering zone 203 and marks the end of the barrier zone. The barrier jetty 206 starts at the beginning of the barrier zone 202 from the active flank of the main bridge 209 with a short-term constant high pitch. After that run the main bridge 209 and the barrier jetty 206 with the same pitch across a large area of the barrier zone 202 parallel to each other. To the end of the barrier zone 202 the barrier jetty runs 206 on the passive flank of the main bridge 209 out. Through the barrier jetty 206 be in the screw channel of the solid channel 208 and the melt channel 207 generated. The pitch of the main bridge remains within the barrier zone 202 unchanged at the level of the intake zone 201 , The orientation of the screw axis is indicated by the arrow 210 characterized.

In this variant of the barrier zone, the width of the solids channel decreases at the beginning of the barrier zone 202 clear. In this way, on the one hand, the possible introduction of energy into the solid is reduced and, on the other hand, the risk of blockage of the solid bed in the solids channel at the beginning of the barrier zone 202 unnecessarily increased. At the same time, it is already shortly after the beginning of the barrier zone 202 the melt channel with a relatively large width before, resulting in a higher energy input into the melt. This unnecessary energy input can lead to an increase in the melt temperature.

4 shows a schematic, not to scale development of the screw channel in the region of the barrier zone, similar to the US 2011217406 A1 described. The dashed line 304 separates the feeder zone as an example 301 from the barrier zone 302 and thus marks the beginning of the barrier zone. The dashed line 305 separates the barrier zone as an example 302 from the metering zone 303 and marks the end of the barrier zone. The gangway of the main bridge 309 becomes the beginning of the barrier zone 302 elevated. The barrier jetty 306 starts at the beginning of the barrier zone with a pitch that is higher than the pitch of the main bridge in the feeder zone 301 , After that run the main bridge 309 and the barrier jetty 306 with the same pitch across a large area of the barrier zone 302 parallel to each other. To the end of the barrier zone 302 the barrier jetty runs 306 on the passive flank of the main bridge 309 out. Through the barrier jetty 306 be in the screw channel of the solid channel 308 and the melt channel 307 generated. The orientation of the screw axis is indicated by the arrow 310 characterized.

In this variant of the barrier zone, the width of the solids channel decreases at the beginning of the barrier zone 302 if at all immaterial and remains throughout much of the barrier zone 302 almost constant. In this way, on the one hand the possible energy input into the solid is kept at a high level and, on the other hand, the risk of blocking of the solid bed in the solids channel at the beginning of the barrier zone 302 reduced. Due to the almost constant course of the width of the solid channel, however, no discontinuous rearrangement processes take place in the solid bed, whereby the degree of performance of the melting of the solid is limited. At the same time, it is already shortly after the beginning of the barrier zone 302 the melt channel with a relatively large width before, resulting in a higher energy input into the melt. This unnecessary energy input can lead to an increase in the melt temperature.

5 shows a schematic, not to scale development of an inventive expression of the screw channel in the area of the barrier zone with main and barrier web. The dashed line 404 separates the feeder zone as an example 401 from the barrier zone 402 and thus marks the beginning of the barrier zone. The dashed line 405 separates the barrier zone as an example 402 from the metering zone 403 and marks the end of the barrier zone 402 , The gangway of the main bridge 409 is in the step area 414 the barrier zone 402 gradually several times at various positions 412 elevated. The gangway of the barrier jetty 406 is in the step area 414 the barrier zone 402 Gradually several times at various positions 411 elevated. To the end of the barrier zone 402 the barrier jetty runs 406 with three incremental pitch changes 415 outside the step area 414 on the passive flank of the main bridge 409 out. Through the barrier jetty 406 be in the screw channel of the solid channel 408 and the melt channel 407 generated. The gradual changes in the pitch of the main bridge 409 outside the step area 414 at the position 416 serves to the width of the complete flight, consisting of solid channel 408 and melt channel 407 to influence. The orientation of the screw axis is indicated by the arrow 410 characterized.

In this variant of the barrier zone, the width of the solids channel decreases at the beginning of the barrier zone 402 if at all immaterial and remains throughout much of the barrier zone 402 almost constant. As a result, on the one hand, the possible energy input into the solid is kept at a high level and, on the other hand, the risk of blocking the solid bed in the solids channel at the beginning of the barrier zone 402 reduced. At the same time lies in the front area of the barrier zone 402 the melt channel with a relatively small width before, resulting in a low energy input into the melt. By gradually in the step area 414 present changes in the pitch of the main bridge 409 at the positions 412 and the barrier jetty 406 at the positions 411 find discontinuous rearrangement processes in a solid bed, resulting in an improved melting of the solid.

6 shows schematically and not to scale the course of the pitch in the step area 514 the barrier zone along the screw axis according to an embodiment of the invention. In the abstract, the gradient of the pitch of the schematic, not to scale, development of the screw channel becomes apparent 5 shown. The dashed line 504 marks the beginning of the barrier zone. The line 516 indicates the course of the pitch of the barrier bar and the line 519 the course of the pitch of the main bridge. Both pitches are in the present example within the step range 514 increased several times in stages to produce discontinuous rearrangement processes in the solid bed.

The 2 to 5 show schematic, not to scale developments of the screw channel, so as to emphasize the essential features of the invention. The scale relationship of the length of the channel to the width is significantly larger. Along the much longer channel (relative to the width), according to the invention significantly more stepwise changes in the pitch can be present than can be represented here in the figures.

1

Einzugszone

2

Barrierezone

3

Meteringzone

4

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

5

Gestrichelte Linie (Trennlinie) zwischen Barrierezone und Meteringzone

6

Barrieresteg

7

Schmelzekanal

8

Feststoffkanal

9

Hauptsteg

10

Richtung der Schneckenachse

101

Einzugszone

102

Barrierezone

103

Meteringzone

104

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

105

Gestrichelte Linie (Trennlinie) zwischen Barrierezone und Meteringzone

106

Barrieresteg

107

Schmelzekanal

108

Feststoffkanal

109

Hauptsteg

110

Richtung der Schneckenachse

201

Einzugszone

202

Barrierezone

203

Meteringzone

204

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

205

Gestrichelte Linie (Trennlinie) zwischen Barrierezone und Meteringzone

206

Barrieresteg

207

Schmelzekanal

208

Feststoffkanal

209

Hauptsteg

210

Richtung der Schneckenachse

301

Einzugszone

302

Barrierezone

303

Meteringzone

304

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

305

Gestrichelte Linie (Trennlinie) zwischen Barrierezone und Meteringzone

306

Barrieresteg

307

Schmelzekanal

308

Feststoffkanal

309

Hauptsteg

310

Richtung der Schneckenachse

401

Einzugszone

402

Barrierezone

403

Meteringzone

404

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

405

Gestrichelte Linie (Trennlinie) zwischen Barrierezone und Meteringzone

406

Barrieresteg

407

Schmelzekanal

408

Feststoffkanal

409

Hauptsteg

410

Richtung der Schneckenachse

411

Positionen von Gangsteigungsänderungen am Barrieresteg innerhalb des Stufenbereiches

412

Positionen von Gangsteigungsänderungen am Hauptsteg innerhalb des Stufenbereiches

414

Stufenbereich in der Barrierezone

415

Positionen von Gangsteigungsänderungen am Barrieresteg außerhalb des Stufenbereiches

416

Position einer Gangsteigungsänderung am Hauptsteg außerhalb des Stufenbereiches

504

Gestrichelte Linie (Trennlinie) zwischen Einzugszone und Barrierezone

514

Stufenbereich in der Barrierezone

516

Verlauf der Gangsteigung des Barrieresteges

519

Verlauf der Gangsteigung des Hauptsteges

List of reference numbers used

1

feed zone

2

barrier zone

3

metering

4

Dashed line (dividing line) between feed zone and barrier zone

5

Dashed line (dividing line) between barrier zone and metering zone

6

barrier flight

7

melt channel

8th

Solids channel

9

main bridge

10

Direction of the screw axis

101

feed zone

102

barrier zone

103

metering

104

Dashed line (dividing line) between feed zone and barrier zone

105

Dashed line (dividing line) between barrier zone and metering zone

106

barrier flight

107

melt channel

108

Solids channel

109

main bridge

110

Direction of the screw axis

201

feed zone

202

barrier zone

203

metering

204

Dashed line (dividing line) between feed zone and barrier zone

205

Dashed line (dividing line) between barrier zone and metering zone

206

barrier flight

207

melt channel

208

Solids channel

209

main bridge

210

Direction of the screw axis

301

feed zone

302

barrier zone

303

metering

304

Dashed line (dividing line) between feed zone and barrier zone

305

Dashed line (dividing line) between barrier zone and metering zone

306

barrier flight

307

melt channel

308

Solids channel

309

main bridge

310

Direction of the screw axis

401

feed zone

402

barrier zone

403

metering

404

Dashed line (dividing line) between feed zone and barrier zone

405

Dashed line (dividing line) between barrier zone and metering zone

406

barrier flight

407

melt channel

408

Solids channel

409

main bridge

410

Direction of the screw axis

411

Positions of pitch changes on the barrier bar within the step area

412

Positions of pitch changes on the main bridge within the step area

414

Step area in the barrier zone

415

Positions of pitch changes on the barrier bar outside the step area

416

Position of a pitch change on the main bridge outside the step area

504

Dashed line (dividing line) between feed zone and barrier zone

514

Step area in the barrier zone

516

Course of the gangway of the barrier barge

519

Course of the pitch of the main bridge

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 3358327 [0007, 0026]
• US 3698541 [0008, 0028]
• DE 2121914 A1 [0009, 0011]
• US 2011217406 A1 [0011, 0030]

Claims (10)

A single-screw plasticizing machine for processing a starting material, preferably for processing thermoplastic polymers or meltable foods, wherein the screw of the single-screw plasticizing machine has at least one barrier zone, characterized in that at least the pitch of one of the two webs present in the barrier zone (main bar, Barrier barrier) in the range of 5% of the axial length of the barrier zone to 50% of the axial length of the barrier zone is gradually changed 3 to 1000 times, preferably 5 to 500 times, 5 to 300 times, 8 to 300 times, 8 to 100 times, especially preferably 10 to 80 times. A single-screw plasticizing machine after Claim 1 , characterized in that the gradual changes in pitch are performed both on the main web and on the barrier web. A single-screw plasticizing machine after Claim 2 , characterized in that the number of incremental changes in the pitch on the main web and barrier web are the same. A single-screw plasticizing machine after Claim 2 , characterized in that the number of gradual changes in the pitch at the main web and barrier web are different. A single-screw plasticizing machine after Claim 1 to 4 , characterized in that the changes in the pitch of the main bar and the barrier bar lead in each case in at least 50% of cases to an increase in gangue, preferably in at least 90% of cases, more preferably in at least 95% of cases. A single-screw plasticizing machine after Claim 1 to 5 , characterized in that the quotient of the projection surface of the melt channel to the cylinder (counter) and the projection surface of the solid channel to cylinder (denominator) on the first 50% of the axial length of the barrier zone is less than 0.35, preferably less than 0, 25, more preferably less than 0.2. A single-screw plasticizing machine after Claim 1 to 6 , characterized in that at least 50% of the stepwise changes in the pitch of the respective web along the screw axis are arranged equidistantly, preferably at least 90%, more preferably at least 95%. A single-screw plasticizing machine after Claim 2 , characterized in that at least 50% of the incremental changes from the barrier web relative to the respective axial position along the screw axis in the same position as the respective stepwise change from the main web, preferably at least 90%, more preferably at least 95%. A single-screw plasticizing machine after Claim 1 , characterized in that at least 30% of the stepwise changes in the pitch of each web have the same amount of change, preferably at least 90%, more preferably at least 95%. A single-screw plasticizing machine after Claim 1 Characterized in that the present step changes a pitch of a web are each so arranged in groups that the transition slope changes are present in a group have the same amount of change and at least one group has at least three gear pitch changes.

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